Georgette N. Jones

Mouse models of altered protein kinase A signaling

Protein kinase A (PKA) is an evolutionarily conserved protein which has been studied in model organisms from yeast to man. Although the cAMP-PKA signaling system was the first mammalian second messenger system to be characterized, many aspects of this pathway are still not well understood. Owing to findings over the past decade implicating PKA signaling in endocrine (and other) tumorigenesis, there has been renewed interest in understanding the role of this pathway in physiology, particularly as it pertains to the endocrine system. Because of the availability of genetic tools, mouse modeling has become the pre-eminent system for studying the physiological role of specific genes and gene families as a means to understanding their relationship to human diseases. In this review, we will summarize the current data regarding mouse models that have targeted the PKA signaling system. These data have led to a better understanding of both the complexity and the subtlety of PKA signaling, and point the way for future studies, which may help to modulate this pathway for therapeutic effect.

Heart-Specific Ablation of Prkar1a Causes Failure of Heart Development and Myxomagenesis

Background— Protein kinase A signaling has long been known to play an important role in cardiac function. Dysregulation of the protein kinase A system, caused by mutation of the protein kinase A regulatory subunit gene PRKAR1A, causes the inherited tumor syndrome Carney complex, which includes cardiac myxomas as one of its cardinal features. Mouse models of this genetic defect have been unsatisfactory because homozygote null animals die early in development and heterozygotes do not exhibit a cardiac phenotype. Methods and Results— To study the cardiac-specific effects resulting from complete loss of Prkar1a, we used cre-lox technology to generate mice lacking this protein specifically in cardiomyocytes. Conditional knockout mice died at day 11.5 to 12.5 of embryogenesis with thin-walled, dilated hearts. These hearts showed elevated protein kinase A activity and decreased cardiomyocyte proliferation before demise. Analysis of the expression of transcription factors required for cardiogenesis revealed downregulation of key cardiac transcription factors such as the serum response factor, Gata4, and Nkx2–5. Although heart wall thickness was reduced overall, specific areas exhibited morphological changes consistent with myxomatous degeneration in the walls of knockout hearts. Conclusions— Loss of Prkar1a from the heart causes a failure of proper myocardial development with subsequent cardiac failure and embryonic demise. These changes appear to be due to suppression of cardiac-specific transcription by increased protein kinase A activity. These biochemical changes lead to myxoma-like changes, indicating that these mice may be a good model with which to study the formation of these tumors.

Targeted Deletion of Prkar1a Reveals a Role for Protein Kinase A in Mesenchymal-to-Epithelial Transition

Dysregulation of protein kinase A (PKA) activity, caused by loss of function mutations in PRKAR1A, is known to induce tumor formation in the inherited tumor syndrome Carney complex (CNC) and is also associated with sporadic tumors of the thyroid and adrenal. We have previously shown that Prkar1a(+/-) mice develop schwannomas reminiscent of those seen in CNC and that similar tumors are observed in tissue-specific knockouts (KO) of Prkar1a targeted to the neural crest. Within these tumors, we have previously described the presence of epithelial islands, although the nature of these structures was unclear. In this article, we report that these epithelial structures are derived from KO cells originating in the neural crest. Analysis of the mesenchymal marker vimentin revealed that this protein was markedly down-regulated not only from the epithelial islands, but also from the tumor as a whole, consistent with mesenchymal-to-epithelial transition (MET). In vitro, Prkar1a null primary mouse embryonic fibroblasts, which display constitutive PKA signaling, also showed evidence for MET, with a loss of vimentin and up-regulation of the epithelial marker E-cadherin. Reduction of vimentin protein occurred at the posttranslational level and was rescued by proteasomal inhibition. Finally, this down-regulation of vimentin was recapitulated in the adrenal nodules of CNC patients, confirming an unexpected and previously unrecognized role for PKA in MET.

Rac1 is required for Prkar1a-mediated Nf2 suppression in Schwann cell tumors

Schwannomas are peripheral nerve sheath tumors that often occur in the setting of an inherited tumor predisposition syndrome, including neurofibromatosis types 1 (NF1) and 2 (NF2), familial schwannomatosis and Carney complex. Loss of the NF2 tumor suppressor (encoding NF2, or Merlin) is associated with upregulation of the Rac1 small GTPase, which is thought to have a key role in mediating tumor formation. In prior studies, we generated a mouse model of schwannomas by performing tissue-specific knockout (KO) of the Carney complex gene Prkar1a, which encodes the type 1A regulatory subunit of protein kinase A. These tumors exhibited down-regulation of Nf2 protein and an increase in activated Rac1. To assess the requirement for Rac1 in schwannoma formation, we generated a double KO (DKO) of Prkar1a and Rac1 in Schwann cells and monitored tumor formation. Loss of Rac1 reduced tumor formation by reducing proliferation and enhancing apoptosis. Surprisingly, the reduction of tumor formation was accompanied by re-expression of the Nf2 protein. Furthermore, activated Rac1 was able to downregulate Nf2 in vitro in a Pak-dependent manner. These in vivo data indicate that activation of Rac1 is responsible for suppression of Nf2 protein production; deficiency of Nf2 in Schwann cells leads to loss of cellular growth control and tumor formation. Further, PKA activation through mutation in Prkar1a is sufficient to initiate Rac1 signaling, with subsequent reduction of Nf2 and schwannomagenesis. Although in vitro evidence has shown that loss of Nf2 activates Rac1, our data indicate that signaling between Nf2 and Rac1 occurs in a bidirectional fashion, and these interactions are modulated by PKA.

Differential role of PKA catalytic subunits in mediating phenotypes caused by knockout of the Carney complex gene Prkar1a.

The Carney complex is an inherited tumor predisposition caused by activation of the cAMP-dependent protein kinase [protein kinase A (PKA)] resulting from mutation of the PKA-regulatory subunit gene PRKAR1A. Myxomas and tumors in cAMP-responsive tissues are cardinal features of this syndrome, which is unsurprising given the important role played by PKA in modulating cell growth and function. Previous studies demonstrated that cardiac-specific knockout of Prkar1a causes embryonic heart failure and myxomatous degeneration in the heart, whereas limited Schwann cell-specific knockout of the gene causes schwannoma formation. In this study, we sought to determine the role of PKA activation in this phenotype by using genetic means to reduce PKA enzymatic activity. To accomplish this goal, we introduced null alleles of the PKA catalytic subunits Prkaca (Ca) or Prkacb (Cb) into the Prkar1a-cardiac knockout (R1a-CKO) or limited Schwann cell knockout (R1a-TEC3KO) line. Heterozygosity for Prkaca rescued the embryonic lethality of the R1a-CKO, although mice had a shorter than normal lifespan and died from cardiac failure with atrial thrombosis. In contrast, heterozygosity for Prkacb only enabled the mice to survive 1 extra day during embryogenesis. Biochemical analysis indicated that reduction of Ca markedly reduced PKA activity in embryonic hearts, whereas reduction of Cb had minimal effects. In R1a-TEC3KO mice, tumorigenesis was completely suppressed by a heterozygosity for Prkaca, and by more than 80% by heterozygosity for Prkacb. These data suggest that both developmental and tumor phenotypes caused by Prkar1a mutation result from excess PKA activity due to PKA-Ca.

Mouse models of endocrine tumours

Since the onset of the genomic era, there has been tremendous progress in identifying the genetic causes of endocrine tumours. Although this knowledge is valuable in its own right, understanding the molecular basis of tumourigenesis allows the development of new therapies targeted at the causative defects. Understanding the connection between genotype and phenotype is a complex process, which can only be partially understood from the analysis of primary tumours or from the studies of cells in vitro. To bridge this gap, genetically modified mice have been developed to allow molecular dissection of the relevant defects in an intact organism. In this article, we discuss the status of genetic modelling for hereditary and sporadic endocrine tumourigenesis with a goal towards providing a view of how this technology will be of future benefit to clinicians developing specifically targeted therapies for endocrine tumours.

Dissection of Complex Genetic and Epigenetic Interactions Underlying NF1 Cancer Susceptibility Using Mouse Models

NF1 is notable for the variable expressivity of the disease. Although NF1 is fully penetrant, patients with the disease show a broad range of phenotypes. This presents a problem for patients and their doctors, because it is difficult to predict which disease complications an individual will develop. This has led to an interest in identifying the sources of phenotypic variation associated with the disease. Inherited factors, environmental factors, and diet can all influence phenotypic variation and differential susceptibility in many diseases, including NF1. Comparison of both inter- and intra-familial phenotypic variance in patients has implicated heritable factors independent of the inherited NF1 allele, as well as environmental factors. Studies in a mouse model of NF1 malignancies have demonstrated that modifier genes unlinked to NF1, as well as the sex of the individual and the inheritance of the disease from the mother or father, affects the risk for developing different types of tumors. Taken together, these data suggest that subtle differences in the genetic and epigenetic background of NF1 patients can have far reaching implications on the risk of developing NF1-associated tumors. In this chapter, we will focus on what is known about heritable factors affecting NF1 variable expressivity in both humans and mouse models. These factors, once characterized, can be used by patients and clinicians to predict the future course of the disease.

Neural Crest-Specific Loss of Prkar1a Causes Perinatal Lethality Resulting from Defects in Intramembranous Ossification

The cranial neural crest (CNC) undergoes complex molecular and morphological changes during embryogenesis in order to form the vertebrate skull, and nearly three quarters of all birth defects result from defects in craniofacial development. The molecular events leading to CNC differentiation have been extensively studied; however, the role of the cAMP-dependent protein kinase [protein kinase A (PKA)] during craniofacial development has only been described in palate formation. Here, we provide evidence that strict PKA regulation in postmigratory CNC cells is essential during craniofacial bone development. Selective inactivation of Prkar1a, a regulatory subunit of the PKA holoenzyme, in the CNC results in perinatal lethality caused by dysmorphic craniofacial development and subsequent asphyxiation. Additionally, aberrant differentiation of CNC mesenchymal cells results in anomalous intramembranous ossification characterized by formation of cartilaginous islands in some areas and osteolysis of bony trabeculae with fibrous connective tissue stabilization in others. Genetic interaction studies revealed that genetic reduction of the PKA catalytic subunit C was able to rescue the phenotype, whereas reduction in C had no effect. Overall, these observations provide evidence of the essential role of proper regulation of PKA during the ossification of the bones of the skull. This knowledge may have implications for the understanding and treatment of craniofacial birth defects. Activation of the Farnesoid X-Activated Receptor Provides Protection against Acetaminophen-Induced Hepatic Toxicity Florence Ying Lee, Thomas Quad de Aguiar Vallim, Hansook Kim Chong, Yanqiao Zhang, Yaping Liu, Stacey A. Jones, Timothy F. Osborne, and Peter A. Edwards (Mol Endocrinol, 10.1210/me.2010-0117) ABSTRACT The nuclear receptor, farnesoid X receptor (FXR, NR1H4), is known to regulate cholesterol, bile acid, lipoprotein, and glucoseThe nuclear receptor, farnesoid X receptor (FXR, NR1H4), is known to regulate cholesterol, bile acid, lipoprotein, and glucose metabolism. In the current study, we provide evidence to support a role for FXR in hepatoprotection from acetaminophen (APAP)-induced toxicity. Pharmacological activation of FXR induces the expression of several genes involved in phase II and phase III xenobiotic metabolism in wild-type, but not Fxr / mice. We used chromatin immunoprecipitation-based genome-wide response element analyses coupled with luciferase reporter assays to identify functional FXR response elements within promoters, introns, or intragenic regions of these genes. Consistent with the observed transcriptional changes, FXR gene dosage is positively correlated with the degree of protection from APAP-induced hepatotoxicity in vivo. Further, we demonstrate that pretreatment of wild-type mice with an FXR-specific agonist provides significant protection from APAP-induced hepatotoxicity. Based on these findings, we propose that FXR plays a role in hepatic xenobiotic metabolism and, when activated, provides hepatoprotection against toxins such as APAP. T R A N S L A T I O N A L H I G H L I G H T S F R O M M O L E C U L A R E N D O C R I N O L O G Y

Tissue-specific ablation of Prkar1a causes schwannomas by suppressing neurofibromatosis protein production

Signaling events leading to Schwann cell tumor initiation have been extensively characterized in the context of neurofibromatosis (NF). Similar tumors are also observed in patients with the endocrine neoplasia syndrome Carney complex, which results from inactivating mutations in PRKAR1A. Loss of PRKAR1A causes enhanced protein kinase A activity, although the pathways leading to tumorigenesis are not well characterized. Tissue-specific ablation of Prkar1a in neural crest precursor cells (TEC3KO mice) causes schwannomas with nearly 80% penetrance by 10 months. These heterogeneous neoplasms were clinically characterized as genetically engineered mouse schwannomas, grades II and III. At the molecular level, analysis of the tumors revealed almost complete loss of both NF proteins, despite the fact that transcript levels were increased, implying posttranscriptional regulation. Although Erk and Akt signaling are typically enhanced in NF-associated tumors, we observed no activation of either of these pathways in TEC3KO tumors. Furthermore, the small G proteins Ras, Rac1, and RhoA are all known to be involved with NF signaling. In TEC3KO tumors, all three molecules showed modest increases in total protein, but only Rac1 showed significant activation. These data suggest that dysregulated protein kinase A activation causes tumorigenesis through pathways that overlap but are distinct from those described in NF tumorigenesis.